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Sinai University Faculty of Engineering Science Department of Basic Science
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Transcript of Sinai University Faculty of Engineering Science Department of Basic Science
Sinai University Faculty of Engineering Science Department of Basic Science
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Course namePhysics II- BSM121
Text books1-Physics for scientists and engineers, Jewett, and Serway 7e2- Fundamental of physics, Haliday et al, 7e3-Lecture notes4- Internet sites
E.M: [email protected]: [email protected]
Edited by: Prof Ahmed Mohamed El-lawindy
Chapter 23
Electric Fields
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23.1 Properties of Electric Charges23.2 Charging Objects By Induction23.3 Coulomb’s Law23.4 The Electric Field23.5 Electric Field of a Continuous Charge Distribution23.6 Electric Field Lines23.7 Motion of Charged Particles in a Uniform Electric Field W1
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Objectives
1- Determine the Properties of Electric Charges.
2- Define and discuss the Coulomb’s Law.
3- Define the Electric Field
4- Apply the concept of electric field to many point charges.
5- Deriving the electric field due to an arbitrary charge distribution,
6- Illustrate the concept of Electric Field Lines
7- Demonstrate the Motion of Charged Particles in a Uniform Electric Field
8- Solve problems related to the electric charges.W1
Electricity and Magnetism, Some History
Many applications Macroscopic and microscopic
Chinese Documents suggest that magnetism was observed as early as 2000 BC
Greeks Electrical and magnetic phenomena as early as 700 BC Experiments with amber and magnetite
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1600 William Gilbert showed electrification effects were not confined to just
amber The electrification effects were a general phenomena
1785 Charles Coulomb confirmed inverse square law form for electric
forces
Electricity and Magnetism, Some History, 2
1819 Hans Oersted found a compass needle deflected when near a wire
carrying an electric current
1831 Michael Faraday and Joseph Henry showed that when a wire is moved
near a magnet, an electric current is produced in the wire
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1873 James Clerk Maxwell used observations and other experimental facts as
a basis for formulating the laws of electromagnetism Unified electricity and magnetism
1888 Heinrich Hertz verified Maxwell’s predictions He produced electromagnetic waves
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23.1 Properties of Electric ChargesExperiments1-After running a comb through your hair on a dry day
you will find that the comb attracts bits of paper.
2-Certain materials are rubbed together, such as glass rubbed with silk or rubber with fur, same effect will appear.
3-Another simple experiment is to rub an inflated balloon with wool. The balloon then adheres to a wall, often for hours.
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Results
When materials behave in this way, they are said to be electrified, or to have become electrically charged.
Example:
Electrify your body:
Electric Charges There are two kinds of electric charges
Called positive and negative Negative charges are the type possessed by electrons Positive charges are the type possessed by protons
Charges of the same sign repel one another
charges with opposite signs attract one another
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More About Electric Charges
1-Electric charge is always conserved in an isolated system
For example, charge is not created
in the process of rubbing two objects
together
The electrification is due to a transfer of charge from one object to another
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Quantization of Electric Charges
2-The electric charge, q, is said to be quantized q is the standard symbol used for charge as a variable Electric charge exists as discrete packets, q = Ne
N is an integer e is the fundamental unit of charge |e| = 1.6 x 10-19 C Electron: q = -e Proton: q = +e
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Conductors
Electrical conductors are materials in which some of the electrons are free electrons Free electrons are not bound to the atoms These electrons can move relatively freely
through the material Examples of good conductors include copper,
aluminum and silver When a good conductor is charged in a small
region, the charge readily distributes itself over the entire surface of the material
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Insulators
Electrical insulators are materials in which all of the electrons are bound to atoms These electrons can not move relatively freely through
the material Examples of good insulators include glass, rubber and
wood When a good insulator is charged in a small region,
the charge is unable to move to other regions of the material
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Semiconductors
The electrical properties of semiconductors are somewhere between those of insulators and conductors
Examples of semiconductor materials include silicon and germanium
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23.2 Charging Objects By Induction
Charging by induction requires no contact with the object inducing the charge
Assume we start with a neutral metallic
sphere (The sphere has the same number of positive and negative charges)
Procedure of the experiment
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-8+8
-4+8
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Charging by induction
Charge Rearrangement in Insulators
A process similar to induction can take place in insulators
The charges within the molecules of the material are rearranged
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23.3 Coulomb’s Law
Charles Coulomb measured the magnitudes of electric forces between two small charged spheres
He found the force depended on the charges and the distance between them
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23.3 Coulomb’s Law
Q
Q Q/2 Q/2
Q/2 Q/4 Q/4
Q/4 Q/8 Q/8
Q/8 Q/16 Q/16
=kFxR=FR
F
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Coulomb’s experiment Results
The electric force between two stationary charged particles
The term point charge refers to a particle of zero size that carries an electric charge The electrical behavior of electrons and protons is
well described by modeling them as point charges
Coulomb’s Law, Equation
Mathematically,
The SI unit of charge is the coulomb (C) ke is called the Coulomb constant
ke = 1/(4πo)= 8.9876 x 109 N.m2/C2
o is the permittivity of free space
o = 8.8542 x 10-12 C2 / N.m2
1 22e e
q qF k
r
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Coulomb's Law, Notes
Remember the charges need to be in coulombs e is the smallest unit of charge
except quarks e = 1.6 x 10-19 C
So 1 C needs 6.24 x 1018 electrons or protons
Typical charges can be in the µC range
Remember that force is a vector quantity
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Particle Summary
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Vector Nature of Electric Forces In vector form,
is a unit vector directed from q1 to q2
The like charges produce a repulsive force between them
Electrical forces obey Newton’s Third Law
The force on q1 is equal in magnitude and opposite in direction to the force on q2
1 212 122
ˆe
q qk
rF r
12r̂
PLAYACTIVE FIGURE
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21 12F F
Vector Nature of Electrical Forces, 3 Two point charges are separated by a
distance r
The unlike charges produce an attractive force between them
With unlike signs for the charges, the product q1q2 is negative and the force is attractive
PLAYACTIVE FIGURE
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Superposition Principle, Example
The force exerted by q1 on q3 is
The force exerted by q2 on q3 is
The resultant force exerted on q3 is the vector sum of and
13F
23F
13F
23F
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23F
13F
F3= +
Zero Resultant Force, Example
Where is the resultant force equal to zero? The magnitudes of the
individual forces will be equal
Directions will be opposite
Will result in a quadratic Choose the root that
gives the forces in opposite directions
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Electrical Force with Other Forces, Example
The spheres are in equilibrium Since they are separated, they exert a
repulsive force on each other Charges are like charges
Proceed as usual with equilibrium problems, noting one force is an electrical force
Solve for |q|
You cannot determine the sign of q, only that they both have same sign
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23.4 The Electric Field Introduction
The electric force is a field force
Field forces can act through space The effect is produced even with no physical
contact between objects
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Electric Field – Definition
An electric field is said to exist in the region of space around a charged object This charged object is the source charge
When another charged object, the test charge, enters this electric field, an electric force acts on it
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Electric Field – Definition, cont
The electric field is defined as the electric force on the test charge per unit charge
The electric field vector, , at a point in space is defined as the electric force acting on a positive test charge, qo placed at that point divided by the test charge:
E
F
oq
FE
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Electric Field, Notes
is the field produced by some charge or charge distribution, separate from the test charge
The existence of an electric field is a property of the source charge The presence of the test charge is not necessary for the field
to exist
The test charge serves as a detector of the field
E
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Electric Field Notes, Final
The direction of is that of the force on a positive test charge
The SI units of are N/C We can also say that an
electric field exists at a point if a test charge at that point experiences an electric force
E
E
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E,F
Relationship Between F and E
This is valid for a point charge only
For larger objects, the field may vary over the size of the object
If q is positive, the force and the field are in the same direction
If q is negative, the force and the field are in opposite directions
e qF E
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Electric Field, Vector Form
Remember Coulomb’s law, between the source and test charges, can be expressed as
Then, the electric field will be
2ˆo
e e
qqk
rF r
2ˆe
eo
qk
q r
FE r
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More About Electric Field Direction
a) q is positive, the force is directed away from q
b) The direction of the field is also away from the positive source charge
c) q is negative, the force is directed toward q
d) The field is also toward the negative source charge
PLAYACTIVE FIGURE
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Superposition with Electric Fields
At any point P, the total electric field due to a group of source charges equals the vector sum of the electric fields of all the charges
2ˆi
e ii i
qk
r E r
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Superposition Example
Find the electric field due to q1, Find the electric field due to q2,
Remember, the fields add as vectors
The direction of the individual fields is the direction of the force on a positive test charge
1E
2E
1 2 E E E
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Electric Field – Continuous Charge Distribution
The distances between charges in a group of charges may be much smaller than the distance between the group and a point of interest
In this situation, the system of charges can be modeled as continuous
The system of closely spaced charges is equivalent to a total charge that is continuously distributed along some line, over some surface, or throughout some volume
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23.5 Electric Field – Continuous Charge Distribution, cont
Procedure: Divide the charge distribution
into small elements, each of which contains Δq
Calculate the electric field due to one of these elements at point P
Evaluate the total field by summing the contributions of all the charge elements
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2ˆ
e
qk
r
E r
2 20ˆ ˆlim
i
ie i eq
i i
q dqk k
r r
E r r
Charge Densities Volume charge density: when a charge is distributed evenly
throughout a volume ρ ≡ Q / V with units C/m3
Surface charge density: when a charge is distributed evenly over a
surface area σ ≡ Q / A with units C/m2
Linear charge density: when a charge is distributed along a line
λ ≡ Q / ℓ with units C/m04/20/23 41W1
Amount of Charge in a Small Volume, Area, and Length
If the charge is nonuniformly distributed over a volume, surface, or line, the amount of charge, dq, is given by
For the volume: dq = ρ dV
For the surface: dq = σ dA
For the length element: dq = λ dℓ04/20/23 42W1
Problem-Solving Strategy
Conceptualize Establish a mental representation of the problem Image the electric field produced by the charges
or charge distribution Categorize
Individual charge? Group of individual charges? Continuous distribution of charges?
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Problem-Solving Strategy, cont Analyze
Units: when using the Coulomb constant, ke, the charges must be in C and the distances in m
Analyzing a group of individual charges: Use the superposition principle, find the fields due to
the individual charges at the point of interest and then add them as vectors to find the resultant field
Be careful with the manipulation of vector quantities Analyzing a continuous charge distribution:
The vector sums for evaluating the total electric field at some point must be replaced with vector integrals
Divide the charge distribution into infinitesimal pieces, calculate the vector sum by integrating over the entire charge distribution
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Problem Solving Hints, final
Analyze, cont. Symmetry:
Take advantage of any symmetry to simplify calculations
Finalize Check to see if the electric field expression is consistent
with your mental representation Check to see if the solution reflects any symmetry present Image varying parameters to see if the mathematical result
changes in a reasonable way
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Example – Charged Disk
The ring has a radius R and a uniform charge density σ
Choose dq as a ring of radius r
The ring has a surface area 2πr dr
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23.6 Electric Field Lines
Field lines give us a means of representing the electric field pictorially
The electric field vector is tangent to the electric field line at each point The line has a direction that is the same as that of the
electric field vector The number of lines per unit area through a surface
perpendicular to the lines is proportional to the magnitude of the electric field in that region
E
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Electric Field Lines, General The density of lines through
surface A is greater than through surface B
The magnitude of the electric field is greater on surface A than B
The lines at different locations point in different directions This indicates the field is
nonuniform
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Electric Field Lines, Positive Point Charge
The field lines radiate outward in all directions In three dimensions, the
distribution is spherical The lines are directed
away from the source charge A positive test charge
would be repelled away from the positive source charge
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Electric Field Lines, Negative Point Charge
The field lines radiate inward in all directions
The lines are directed toward the source charge A positive test charge
would be attracted toward the negative source charge
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Electric Field Lines – Dipole
The charges are equal and opposite
The number of field lines leaving the positive charge equals the number of lines terminating on the negative charge
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Electric Field Lines – Like Charges
The charges are equal and positive
The same number of lines leave each charge since they are equal in magnitude
At a great distance, the field is approximately equal to that of a single charge of 2q
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Electric Field Lines, Unequal Charges The positive charge is twice the
magnitude of the negative charge
Two lines leave the positive charge for each line that terminates on the negative charge
At a great distance, the field would be approximately the same as that due to a single charge of +q
Use the active figure to vary the charges and positions and observe the resulting electric field
PLAYACTIVE FIGURE
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Electric Field Lines – Rules for Drawing
The lines must begin on a positive charge and terminate on a negative charge In the case of an excess of one type of charge, some
lines will begin or end infinitely far away
The number of lines drawn leaving a positive charge or approaching a negative charge is proportional to the magnitude of the charge
No two field lines can cross Remember field lines are not material objects, they
are a pictorial representation used to qualitatively describe the electric field
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23.7 Motion of Charged Particles in a UniformElectric Field
If there is no other forces on the charged
mass, m , then ma=qE,
a is the acceleration, q is its charge
If E is uniform, then the acceleration is constant If the particle has a positive charge, its acceleration
is in the direction of the field If the particle has a negative charge, its acceleration
is in the direction opposite the electric field Since the acceleration is constant, the kinematic
equations can be used
E
F=qE+
Electron in a Uniform Field, Example
The electron is projected horizontally into a uniform electric field
The electron undergoes a downward acceleration It is negative, so the acceleration is
opposite the direction of the field Its motion is parabolic while
between the plates
PLAYACTIVE FIGURE
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The Cathode Ray Tube
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Assignments
1- Electric field lines are not real, write a comment, next week 2- Read examples 23-9 and 23-10. You will be asked
to derive in next weekSolve the following problems2,7,15,21,27,34